From air to stone: The fig trees fighting climate change
- Date:
- July 6, 2025
- Source:
- European Association of Geochemistry
- Summary:
- Kenyan fig trees can literally turn parts of themselves to stone, using microbes to convert internal crystals into limestone-like deposits that lock away carbon, sweeten surrounding soils, and still yield fruit—hinting at a delicious new weapon in the climate-change arsenal.
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Some species of fig trees store calcium carbonate in their trunks – essentially turning themselves (partially) into stone, new research has found. The team of Kenyan, U.S., Austrian, and Swiss scientists found that the trees could draw carbon dioxide (CO2) from the atmosphere and store it as calcium carbonate ‘rocks’ in the surrounding soil.
The research is being presented this week at the Goldschmidt conference in Prague.
The trees – native to Kenya – are one of the first fruit trees shown to have this ability, known as the oxalate carbonate pathway.
All trees use photosynthesis to turn CO2 into organic carbon, which forms their trunk, branches, roots and leaves; this is why planting trees is seen as a potential means to mitigate CO2 emissions.
Certain trees also use CO2 to create calcium oxalate crystals. When parts of the tree decay, these crystals are converted by specialised bacteria or fungi into calcium carbonate – the same mineral as limestone or chalk. This increases the soil pH around the tree, while also increasing the availability of certain nutrients. The inorganic carbon in calcium carbonate typically has a much longer lifetime in the soil than organic carbon, making it a more effective method of CO2 sequestration.
Dr Mike Rowley, senior lecturer at the University of Zurich (UZH) is presenting the research at the Goldschmidt conference. He said: “We’ve known about the oxalate carbonate pathway for some time, but its potential for sequestering carbon hasn’t been fully considered. If we’re planting trees for agroforestry and their ability to store CO2 as organic carbon, while producing food, we could choose trees that provide an additional benefit by sequestering inorganic carbon also, in the form of calcium carbonate.”
The team, from UZH, the Nairobi Technical University of Kenya, Sadhana Forest, Lawrence Berkeley National Laboratory, University of California, Davis, and the University of Neuchatel studied three species of fig tree grown in Samburu County, Kenya. They identified how far from the tree the calcium carbonate was being formed and identified the microbial communities involved in the process. Using synchrotron analysis at the Stanford Synchrotron Radiation Lightsource, they found that calcium carbonate was being formed both on the exterior of tree trunks and deeper within the wood.
Dr Rowley explained: “As the calcium carbonate is formed, the soil around the tree becomes more alkaline. The calcium carbonate is formed both on the surface of the tree and within the wood structures, likely as microorganisms decompose crystals on the surface and also, penetrate deeper into the tree. It shows that inorganic carbon is being sequestered more deeply within the wood than we previously realised.”
Of the three types of fig tree studied, the scientists found thatFicus wakefieldii was the most effective at sequestering CO2 as calcium carbonate. They are now planning to assess the tree’s suitability for agroforestry by quantifying its water requirements and fruit yields and by doing a more detailed analysis of how much CO2 can be sequestered under different conditions.
Most of the research into the oxalate-carbonate pathway has been in tropical habitats and focused on trees that do not produce food. The first tree to be identified as having an active oxalate-carbonate pathway was the Iroko (Miliciaexcelsa). It can sequester one ton of calcium carbonate in the soil over its lifetime.
Calcium oxalate is one of the most abundant biominerals and the crystals are produced by many plants. The microorganisms that convert calcium oxalate to calcium carbonate are also widespread.
“It’s easier to identify calcium carbonate in drier environments” explained Dr Rowley. “However, even in wetter environments, the carbon can still be sequestered. So far, numerous species of tree have been identified which can form calcium carbonate. But we believe there are many more. This means that the oxalate-carbonate pathway could be a significant, underexplored opportunity to help mitigate CO2 emissions as we plant trees for forestry or fruit.”
The Goldschmidt Conference is the world’s foremost geochemistry conference. It is a joint congress of the European Association of Geochemistry and the Geochemical Society (US) and 4000 people are expected to attend. It takes place in Prague, Czech Republic, from July 6-11, 2025.
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